Direct digital frequency generation using time and amplitude

ABSTRACT

This application discusses, among other things, apparatus and methods for sharing a local oscillator between multiple wireless devices. In certain examples, an apparatus can include a central frequency synthesizer configured to provide a central oscillator signal having a first frequency, a first transmitter, the first transmitter including a first transmit digital-to-time converter (DTC) configured to receive the central oscillator signal and to provide a first transmitter signal having a second frequency, and a first receiver, the first receiver including a first receive DTC configured to receive the central oscillator signal and to provide a first receiver signal having a first receive frequency.

CLAIM OF PRIORITY AND RELATED APPLICATIONS

This application is a continuation of, and claims the benefit ofpriority to, U.S. patent application Ser. No. 14/997,056, filed Jan. 15,2016, which is a continuation of, and claims the benefit of priority to,Lakdawala et al., U.S. patent application Ser. No. 14/138,508, titled,“DIRECT DIGITAL FREQUENCY GENERATION USING TIME AND AMPLITUDE”, filedDec. 23, 2013, now issued as U.S. Pat. No. 9,288,841, each of which ishereby incorporated by reference herein in its entirety.

TECHNICAL FIELD

Examples described herein refer to synthetic signal generation, and moreparticularly, to synthetic frequency signal generation.

BACKGROUND

Multi-standard radios, such as cell phones and other electronic devices,require multiple signals having different frequencies to be able totransmit and receive information from different frequency bands. Due tocarrier aggregation in cellular communication technologies, newer radiowill be capable of operating multiple radios simultaneously. Presenttopologies have an individual synthesizer associated with each differentfrequency signal.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings, which are not necessarily drawn to scale, like numeralsmay describe similar components in different views. Like numerals havingdifferent letter suffixes may represent different instances of similarcomponents. The drawings illustrate generally, by way of example, butnot by way of limitation, various embodiments discussed in the presentdocument.

FIG. 1 illustrates generally a multi-radio device including twotransmitter devices and two receiver devices.

FIGS. 2A-2C illustrate generally example frequency synthesizers orfrequency generators that can include a digital-to-time converter (DTC).

FIG. 3 illustrates generally an example DTC for generating an arbitraryoscillator signal from a central oscillator signal.

FIG. 4 illustrates an additional example of a DTC\ for generating anoutput oscillator signal.

FIG. 5 illustrates generally an example central frequency synthesizerbased transceiver.

FIG. 6 illustrates graphically an example frequency plan of an examplemulti-radio device.

FIG. 7 illustrates graphically a frequency plan for a fraction DTC-basedsynthesizer such as the example fractional DTC-based synthesizerillustrated in FIG. 8.

FIG. 8 illustrates an example communication module of a MIMO deviceincluding two transmitters and two receivers.

FIG. 9 illustrates generally an example communication device including aMIMO stack and carrier aggregation section.

FIG. 10 illustrates generally an example method of using a centralfrequency synthesizer.

DETAILED DESCRIPTION

Multi-standard radios, such as cell phones and other electronic devices,require multiple signals having different frequencies to be able totransmit and receive information from different frequency bands. Due tocarrier aggregation in cellular communication technologies, newer mobiledevices will be capable of operating multiple radios simultaneously.Present topologies have a separate oscillator and synthesizer associatedwith each different frequency signal. Current multi-radio architecturespressure the devices to be larger to accommodate the additionaloscillators. The additional oscillators also use additional power thatcan substantially reduce the time between recharging of the energystorage device of mobile devices without making accommodations for alarger energy storage device.

Recent developments in standards and technology have introduced theconcept of carrier aggregation and amplifiers integrated with thetransmitters or transceivers. These technological improvements have comewith costs. For example, the oscillator in each radio PLL of currentdesigns can experience “pulling” from the high power modulated poweramplifier outputs. “Pulling” from the power amplifier to the localoscillator (e.g., re-modulation) can result in degraded modulationquality and spectral performance. The pulling problem can be exacerbatedwith multi-input/multi-output (MIMO) transmitters where the multipleindependently modulated power amplifiers at the same frequency can“pull” the transmitter modulation PLLs. The oscillator in the PLLs foreach MIMO or carrier aggregation branch can pull one another as well.

FIG. 1 illustrates generally a multi-radio device 100 including twotransmitter devices 101, 102 and two receiver devices 103, 104. Eachdevice can include a processor such as a digital signal processor (DSP)105 _(n). The transmitter devices 101, 102 can include a transmitter,such as a Cartesian transmitter or a polar transmitter including acordic converter 106, sample rate converter 107, digital-to-analogconverter (DAC) 108, a mixer 109 and a power amplifier 110. Eachreceiver device 103, 104 can include a receiver amplifier 111, a phaseshifter 112, one or more mixers 113 and a demodulator 114. Each devicealso includes a synthesizer 115 to generate a local oscillator (LO)signal associated with the wireless signal generated by a transmitterdevice 101, 102 or received by a receiver device 103, 104. As discussedabove, having a synthesizer 115 for each device 101, 102, 103, 104 canlimit the ability of multi-radio devices to miniaturize. In addition,each synthesizer 115, as well as, the power amplifiers of each radio caninfluence or pull the frequency of other synthesizer devices diminishingthe devices performance or fidelity. Therefore, it can be customary tomaximize distance between the synthesizers 115 which can also limitminiaturization of multi-radio devices.

The present inventors have recognized a synthetic frequency synthesisarchitecture that allows multiple frequency generation using a centralfrequency synthesizer such as a single central phase-locked loop (PLL),for example. The architecture allows selection of a central PLLfrequency to be at a power efficient frequency. Frequencies for eachradio of the device can be generated with a power efficient directdigital frequency synthesizer using the output of the central PLL. Thedirect digital frequency synthesizers can use time and voltageinformation to reduce phase noise, improve performance, and decouple thetraditional mechanism that allows the power amplifier to “pull” thelocal oscillator. An unexpected development of solving the “pulling”problem, the inventors have also recognized that a central PLLarchitecture that exploits the digital phase shifting capabilities of adigital-to-time converter (DTC) can significantly reduce circuit realestate in transmitter/receiver radios and more so in MIMO devices havingmultiple transmitters, multiple receivers, or combinations of multipletransmitters and multiple receivers.

FIGS. 2A-2C illustrate generally a portion of an example frequencygeneration circuit 225 that can include a digital-to-time converter(DTC) 220 and a summing node 221. In certain examples, the DTC canreceive an oscillator signal (f_(i)), for example, from a centralfrequency synthesizer or central frequency generator and can generate aoutput oscillator signal (f_(o)) having a different characteristics thanthe received oscillator signal (f_(i)). Referring to FIG. 2A, in certainexamples, a second input signal from the summing node 221 can include aphase ramp (ψ) and the output oscillator signal (f_(o)) can have afrequency offset or shifted from the frequency of the input oscillatorsignal (f_(i)). Referring to FIG. 2B, in certain examples, the secondinput signal can include a phase modulation information (φ) and theoutput oscillator signal (f_(o)) can be a modulated output signal havinga nominal frequency the same as the input oscillator frequency.Referring to FIG. 2C, in certain examples, the second input signal caninclude a phase ramp (ψ) and phase modulation information (φ), and theoutput oscillator signal (f_(o)) can be phase modulated and can have afrequency offset or shifted from the frequency of the input oscillatorsignal (f_(i)).

FIG. 3 illustrates generally an example DTC 320 for generating anarbitrary oscillator signal from a central oscillator signal. In certainexamples, the DTC 320 can include an interpolated low latency delay line330 or a ring oscillator configured to receive the central oscillatorsignal (LO). Taps of the delay line 330 or ring oscillator can bereceived at a multiplexer 331 configured to output one or more of thetap lines to provide a synthesized frequency signal. In certainexamples, the DTC 320 can optionally include one or more currentdigital-to-analog converters (iDACs) 332. The iDACs can receive outputsof the multiplexer and can receive weight values from a controller. Insuch a configuration the weighted gain of the iDACS can allowsuppression of phase noise at particular frequencies. In certainexamples, phase ramp information (ψ) can be received by a controller 333and can be used to control the selection of the multiplexer 331,weighting of the iDACs 332, or combinations thereof, to generate anarbitrary oscillator signal (f_(o)) having a desired frequency. Incertain examples, the phase ramp information can be combined with phasemodulation information to provide a modulated oscillator signal, forexample, for a polar transmitter.

FIG. 4 illustrates an additional example of a DTC 420 for generating anoutput oscillator signal (f_(o)). In certain examples, the DTC 420 caninclude a tapped delay line (TDL) 434 for receiving a central oscillatorsignal (LO), a multiplexer 435, a lookup table 436 and a digitallycontrolled delay line (DCDL) 437. In certain examples, the lookup table436 can decode phase modulation information (φ) to provide coarseplacement of signal edges of the output signal (f_(o)) using the TDL 434and the multiplexer 435. In certain examples, the lookup table candecode the phase modulation information (φ) to provide fine placement ofsignal edges of the output signal (f_(o)) using delay registers 438coupled to the DCDL 437 to provide the desired phase modulation of theoutput signal (f_(o). In certain examples, the DTC 420 can unwrap phaseselection of the central oscillator signal (LO) thus providing moreappropriate input edge selection that allows the DTC 420 to implementfrequency multiplication or frequency division within the DTC 420. Incertain examples, the phase modulation information (φ) can include aphase ramp that can use the phase unwrapping of the DTC 420 such thatthe phase modulated output signal (f_(o)) provided by the DTC 420includes a frequency different from the frequency of the centraloscillator signal (LO). In certain examples, this arbitrary frequencygeneration feature can allow a wireless device to avoid frequencypulling problems where the powerful modulated output signal of awireless device can pull or add phase noise to the local oscillator ator near the frequency of the output signal or a harmonic of the outputsignal. It is understood that other implementations of DTCs are possiblewithout departing from the scope of the present subject matter,including, but not limited to, delay lines, dividers, delayinterpolators or combinations thereof.

FIG. 5 illustrates generally an example central frequency synthesizerbased transceiver 500 for exchanging information between a processor ofa wireless device and a processor of one or more other devices using awireless network or communication link. The transceiver 500 can includetransmitter 501 and a receiver 503. The transmitter 501 can include aprocessor 505, such as a digital signal processor (DSP), a transmitter540 and a power amplifier 510. The processor 505 can receive transmitdata from a host processor (not shown), such as a baseband processor ofa cell phone, for example, and can provide transmit information to thepolar transmitter 540. In certain examples, the transmitter 540 canprocess the transmit information to provide a modulated radio frequency(RF) signal to the power amplifier 510. The power amplifier 510 canamplify and process the RF signal for transmission using an antenna (notshown). In certain examples, the DTC-based frequency synthesis canreceive phase ramp information to provide a particular radio frequencyfor transmission, reception or both transmission and reception. In someexamples, such as for some polar transmitters, the DTC-based frequencysynthesis can receive phase modulation information or a combination ofphase modulation information and phase ramp information to provide aphase modulated signal at a particular radio frequency for transmission.In some examples, the transmitter can include a polar transmitter 540and can include an amplitude processing path 541 for processing digitalamplitude symbols of the transmit data and a phase processing path 542for processing digital phase symbols of the transmit information. Thephase processing path 542 can include a central frequency synthesizer515, to provide central frequency information, and a transmitter DTC 543to a particular frequency for the RF signal using the central frequencyinformation or to provide the particular frequency and modulate thephase of the RF signal using the central frequency information. Incertain examples, a mixer 509 can add the amplitude information to theenvelope of the RF signal to provide the modulated RF signal. In certainexamples, the polar transmitter 540 can include a cordic converter 506to convert the transmit information of the DSP from Cartesian symbols(I, Q) to polar symbols (AM, PM+f). Although FIG. 5 illustrates a polartransmitter, the ability of implementing a DTC to provide frequencyshifting, frequency modulation, or both frequency shifting and frequencymodulation is not limited to only polar transmitters but othercommunication devices including receivers and other transmitters such ascartesian transmitters and out-phasing transmitters.

The receiver 503 can include an amplifier 511, demodulator 544, areceiver DTC 545, a analog-to-digital converter (ADC) 546 and aprocessor 547, such as a receiver DSP. In certain examples, an antennacoupled to the receiver 503 can receive a wireless signal. The amplifier511 can amplify the wireless signal; or certain portions of the wirelesssignal. The demodulator 544 can extract information from the wirelesssignal using a frequency provided by the receiver DTC 545. The ADC 546can convert the information from an analog form to digital informationfor further processing by the processor 547. The processor 547 canprovide at least a portion of the information to a host processor suchas the baseband processor. In certain examples, the receiver DTC 545uses the central frequency information generated by the centralfrequency synthesizer 515 to provide the demodulation frequency for thedemodulator 544. In certain examples, pulling effects of the poweramplifier 510 on the central frequency synthesizer 515 are significantlyreduced or eliminated because the power amplifier 510 is prevented fromcoupling to the digitally implemented DTCs 543, 545 and there is noinductive coil as can be found with other architectures. In certainexamples, the transmit DTC 543 and the receive DTC 545 can be employedto provide a frequency shift for generating transmit and receivefrequencies. Exploiting this capability of the DTC allows transmissionand reception frequencies to be different from the frequency of thecentral frequency synthesizer 515. Furthermore, in addition toeliminating a mechanism for allowing “pulling” of a transmitter orreceiver local oscillator, the example architecture can unexpectedlyprovide real estate savings over traditional transceivers. Traditionaltransceivers typically have a local oscillator for each transmitter andreceiver. Such oscillators can take up significant room on their own andthen may require addition room to provide adequate separation betweenthe oscillators or other components that can influence the frequency ofthe oscillators. The digital nature of the example architecture and thesharing of a central frequency synthesizer can eliminate the largecomponents (e.g. coils) of the traditional local oscillator and canallow transmitter and receiver phase modulation to be done in a small,low-noise, digital environment.

FIG. 6 illustrates graphically an example frequency plan of an examplemulti-radio device. The plan shows the relative separation of certainfrequencies associated with the multi-radio device. The plan shows atransmitter frequency different (Tx₀) from a receiver frequency (Rx₀)and a frequency of the central frequency synthesizer (LO) different fromboth the transmitter frequency (Tx₀) and the receiver frequency (Rx₀).In addition, the plan illustrates that by exploiting the frequency shiftcapability of the DTCs, the frequency (LO) of the central frequencysynthesizer can be selected to avoid harmonics (Rx₁₋₃, Tx₁₋₃) of thetransmitter frequency (Tx₀), and the receiver frequency (Rx₀).

FIG. 7 illustrates graphically a frequency plan for a fractionalDTC-based synthesizer such as the example synthesizer illustrated inFIG. 8. The frequency plan illustrated in FIG. 7 includes frequencybands for two transmitters and three receivers. Of interest in thefrequency plan is that the receiver frequencies (R1x₀, R2x₀, R3x₀) donot overlap the transmitter frequencies (T1x₀, T2x₀) or any of thetransmitter frequency harmonics (T1x₁₋₃, T2x₁). Nor do any of thefrequencies (R1x0, R2x0, R3x0, T1x0, T2x0) or harmonics (T1x₁₋₃, T2x₁)overlap the frequency (LO) of the central frequency synthesizer. Such aconfiguration provides significant resistance to “pulling” between thetransmitters and receivers.

FIG. 8 illustrates an example communication module 800 of a MIMO deviceincluding two transmitters 801, 802 and two receivers 803, 804. Thecommunication module 800 can include a central frequency synthesizer 815for generating central frequency information. The central frequencyinformation can be used by a DTC 820 of each transmitter 801, 802 andreceiver 803, 803 to develop the local oscillator signal for modulationor demodulation. The example architecture of FIG. 8 can be extended toinclude additional transmitters and receivers. Devices implementingsimultaneous wireless communication standards can make space efficientuse of the example architecture shown in FIG. 8. Such standards orprotocols can include, but are not limited to Bluetooth, Wi-Fi, GPS, CR,etc.

In certain examples, a central synthesizer architecture can provide theopportunity to optimize the frequency of the central synthesizer. Forexample, the central synthesizer frequency can be selected to minimizecross talk between different device systems implemented or operatedsimultaneously in a mobile phone. In certain examples, the examplecentral frequency synthesizer architecture can allow power scaling basedon performance requirements of a certain RF mode. For example, currentallocation and resolution, for example of one or more DTCs, can beadjusted depending on the operating mode of one or more of the radios ofa mobile device. More specifically, for example, current consumption andDTC resolution can be decreased if a MIMO device is operating in aBluetooth-only mode.

Emerging radio standards or protocols for connectivity (e.g., 802.11ac)and cellular (e.g., LTE-Rel10 and beyond) can incorporate contiguous andnon-contiguous channel bonding/carrier aggregation features to supportwide effective channel bandwidths while maintaining backwardcompatibility with legacy networks and existing spectrum allocation.This incorporation can allow peak data rates on the order of 100 Mbps-5Gbps, and higher, to be supported on the up-links and down-links tomobile devices. In certain examples, architecture according to thepresent subject matter can allow mobile devices to also support transmit(TX) multi-input, multi-output (MIMO) capabilities to further improvechannel capacity in these standards.

Digital polar transmitters are a promising approach for radioimplementations on low-cost SoC CMOS because they can offer thepotential for higher efficiency, minimize the required number ofarea-intensive passives, and port easily to new process nodes. PLL basedphase modulators are typically used to generate the desired TX signalsbut suffer limitations when used for wider bandwidth (e.g., >20 MHz.)signals. Carrier aggregation can simultaneously generate transmitsignals at non-harmonically related channel frequencies. Since, thespectrum allocation for cellular services varies by geography, a“world-phone” may need to generate transmit signals in many differentbands, even if they do not need to operate simultaneously. Generatingthese modulated transmit signals in multiple independent PLLs, one foreach carrier frequency, can result in significant area and powerpenalties. With the integration of power amplifier (PA) on the same dieas the RF transceiver, the oscillator in each PLL can experience“pulling” from the high power modulated PA outputs. PA LO pulling(re-modulation) can result in degraded modulation quality and spectralperformance. This problem can be exacerbated with TX-MIMO, where themultiple independently modulated PAs at the same frequency can pull theTX modulation PLLs. The oscillators in the PLLs for each MIMO or carrieraggregation branch can pull one another as well.

Existing or proposed schemes to alleviate pulling by shifting theoscillator frequency from the power amplifier output, such asdividing-and-mixing or harmonic division, can require area intensivepassive filters such as inductive-capacitive (LC) filters. Such schemesmay not be immune to harmonic pulling and do not scale well as thenumber of carrier frequencies increase. All digital local oscillatorschemes can separate the power amplifier output from the localoscillator frequency without including passive filters but still consumesubstantial chip area and power.

A conventional solution for carrier aggregation and MIMO is to generatemultiple transmission signals using multiple phased-locked loops, onefor each frequency band that is supported whether the bands are usedconcurrently or not. Such solutions use significant circuit area andpower and are susceptible to pulling, sometimes referred to asre-modulation, from the multiple local oscillator signals and harmonicsthereof.

FIG. 9 illustrates generally an example communication device 900including a MIMO stack 930 and carrier aggregation section 931 that canalleviate power amplifier pulling and other forms of frequency pulling.The shared local oscillator (LO) scheme can provide pulling immune,low-power, and area efficient transmitters that can allow carrieraggregation and transmit MIMO support, such as IEEE 802ac, LTE,LTE-Advanced and future high data rate wireless standard radios. Incertain examples, the shared local oscillator (LO) scheme conservespower by introducing phase shifts in the same phase modulator used forthe transmitter.

The MIMO stack 930 and the carrier aggregation section 931 can includemultiple transmitters 933 _(n). In certain examples, each transmitter933 _(n) can be a digital polar transmitter including a power amplifier934 _(n), a DTC 935 _(n), and a summing junction 936 _(n). The summingjunction 936 _(n) can receive phase modulation information (φ_(n)) and aphase ramp (ψ_(n)). The DTC 935 _(n) can provide a phase modulatedsignal having a frequency different from a signal received from a localoscillator (LO) using the phase modulation information (φ_(n)) and thephase ramp (ψ_(n)). In certain example, the power amplifier 934 _(n) canadd amplitude information (ρ_(n)) to the envelope of the phase modulatedsignal of the DTC 935 _(n) to provide a radio frequency signal RF_(n) todrive one or more antennas

In certain examples, a MIMO stack 930 can provide multiple modulatedsignals using a common frequency. As illustrated, a first DTC 935 ₁ anda second DTC 935 ₂ of the MIMO stack 930 can receive the same phase ramp(ψ₁) but different phase modulation information (φ₁, φ₂). Each DTC 935₁, 935 ₂ can provide a phase modulated signal to a respective poweramplifier 934 ₁, 934 ₂. Each power amplifier 934 ₁, 934 ₂ can addamplitude information (ρ₁, ρ₂) to the respective phase modulated signaland can provide a radio frequency drive signal (RF₁, RF₂) for anantenna.

In certain examples, a carrier aggregation section 931 can include threetransmitters 933 ₃, 933 ₄, 933 ₅. Each DTC 935 ₃, 935 ₄, 935 ₅ canreceive different phase modulation information (φ₃, φ₄, φ₅) anddifferent phase ramp information (ψ₃, ψ₄, ψ₅) to produce three differentphase modulated signal, each having a different frequency offset fromthe frequency of the local oscillator (LO). In addition, each poweramplifier 934 ₃, 934 ₄, 934 ₅ of each of the carrier aggregation sectiontransmitters 933 ₃, 933 ₄, 933 ₅ can receive different amplitudeinformation (ρ₃, ρ₄, ρ₅) for providing a radio frequency signal (RF₃,RF₄, RF₅) for driving an antenna.

In certain examples, the open loop DTCs 935 _(n) can receive a phaseramp (ψ_(a)) to offset the output frequency from the frequency of thelocal oscillator (LO) and thereby absorb the function of a conventionalfractional multiplier/divider. The range of frequency fractionalitiessynthesized using a DTC can be set by the resolution of the DTC, and theoutput frequency range of the DTC can be determined by the maximuminstantaneous frequency jump the DTC can handle. In certain examples,additional integer frequency dividers can expand the flexibility of thearchitecture to cover a wide range of bands without being susceptible tofrequency pulling. It is understood that the illustrated example caninclude additional transmitters as well as corresponding receivers, asis discussed above with respect to FIG. 8, without departing from thescope of the present subject matter. In some examples, one or more ofthe DTCs 935 _(n), or additional DTCs associated with one or morereceivers, can optionally receive only phase ramp information, such asis shown in FIG. 2A, to shift the local oscillator (LO) frequency and toprovide a particular frequency for a transmitter or a receiver.

FIG. 10 illustrates generally an example method 1000 of using a centralfrequency synthesizer. At 1001, a central frequency synthesizer, such asa single phase-locked loop (PLL), can generate a central synthesizedsignal. At 1002, a first DTC can receive the central synthesized signal.At 1003, the first DTC can provide a first transmitter signal using thecentral synthesized signal. Ire certain examples, the frequency of thefirst transmitter signal can be different than the frequency of thecentral synthesized signal and integer harmonics of the centralsynthesized signal to, for example, prevent frequency pulling. At 1004,a second DTC can receive the central synthesized signal. At 1005, thesecond DTC can provide a first receiver signal using the centralsynthesized signal. In certain examples, the frequency of the firstreceiver signal can be different than one or more of the frequency ofthe central synthesized signal, integer harmonics of the centralsynthesized signal, and the frequency of the first transmitter signal.

Additional Notes

In Example 1, an apparatus can include a central frequency synthesizerconfigured to provide a central oscillator signal having a firstfrequency, a first transmitter, the first transmitter including a firsttransmit digital-to-time converter (DTC) configured to receive thecentral oscillator signal and to provide a first transmitter signalhaving a second frequency, and a first receiver, the first receiverincluding a first receive DTC configured to receive the centraloscillator signal and to provide a first receiver signal having a firstreceive frequency. In certain examples, the second frequency can bedifferent from the first frequency

In Example 2, the first transmitter of Example 1 optionally isconfigured to process and transmit first information according to afirst communication protocol, and the first receiver of Example 1optionally is configured to receive and process second informationaccording to the first communication protocol.

In Example 3, the apparatus of any one or more of Examples 1-2optionally includes a second transmitter, the second transmitterincluding a second transmit DTC, the second transmit DTC configured toreceive the central frequency and to provide a second transmittersignal.

In Example 4, the second transmitter of any one or more of Examples 1-3optionally is configured to process and transmit third informationaccording to a communication protocol different from the firstcommunication protocol.

In Example 5, the first transmit DTC of any one or more of Examples 1-4optionally is configured to receive first phase ramp information and toprovide the first transmitter signal having the second frequency usingthe first phase ramp information.

In Example 6, the second transmit DTC of any one or more of Examples 1-5optionally is configured to receive second phase ramp information and toprovide the second transmitter signal using second phase rampinformation.

In Example 7, the first phase ramp information and the second phase rampinformation of any one or more of Examples 1-6 optionally are the same.

In Example 8, the first phase ramp information and the second phase rampinformation of any one or more of Examples 1-6 optionally are different.

In Example 9, the first frequency of any one or more of Examples 1-8optionally is different from the second frequency.

In Example 10, the first frequency of any one or more of Examples 1-9optionally is different from the first receive frequency.

In Example 11, the second frequency of any one or more of Examples 1-10optionally is different from the first receive frequency.

In example 12, the second frequency and the first receive frequency ofany one or more of Examples 1-11 optionally are different from aninteger harmonic frequency of the first frequency.

In Example 13, the first transmitter signal of any one or more ofExamples 1-12 optionally includes a first modulated signal, and thefirst DTC of any one or more of Examples 1-12 optionally is configuredto receive first phase ramp information and phase modulation informationand to provide the first modulated signal using the first phase rampinformation and the phase modulation information.

In Example 14, a method can include generating a central synthesizedsignal for a plurality of communication circuits of an electronic deviceusing a central frequency synthesizer, receiving the central synthesizedsignal at a first digital-to time converter (DTC) of a first transmitterof the plurality of communication circuits, providing a firsttransmitter signal having a first transmitter frequency different from anominal frequency of the central synthesized signal using the first DTC,receiving the central synthesized signal at a second DTC of a firstreceiver of the of the plurality of communication circuits, andproviding a first receiver signal having a first receiver frequencydifferent from the nominal frequency of the central synthesized signalusing the second DTC.

In Example 15, the method of any one or more of Examples 1-14 optionallyincludes receiving the central synthesized signal at a third DTC, andproviding a second transmitter signal having a third frequency using thethird DTC. In certain examples, a second transmitter of the plurality ofcommunication circuits can optionally include the third DTC.

In Example 16, the method of any one or more of Examples 1-15 optionallyincludes processing first transmission data according to a firstcommunication protocol using the first transmitter, and processingsecond transmission data according to a second communication protocolusing the second transmitter.

In Example 17, the first communication protocol of any one or more ofExamples 1-16 optionally is different from the second communicationprotocol.

In Example 18, the method of any one or more of Examples 1-17 optionallyincludes receiving communication data from an antenna coupled to thefirst receiver, and processing the communication data according to thefirst communication protocol.

In Example 19, the first frequency of any one or more of Examples 1-18optionally is different from the third frequency.

In Example 20, the second frequency of any one or more of Examples 1-19optionally is different from the third frequency.

In Example 21, an integer harmonic frequency of the nominal frequency ofany one or more of Examples 1-20 optionally is different from the firstfrequency, the second frequency, and the third frequency.

In Example 22, the providing the first transmitter signal of any one ormore of Examples 1-21 optionally includes receiving first phase rampinformation at the first DTC.

In Example 23, the providing the second transmitter signal of any one ormore of Examples 1-22 optionally includes receiving second phase rampinformation at the third DTC.

In Example 24, the first phase ramp information of any one or more ofExamples 1-23 optionally is the same as the second phase rampinformation.

In Example 25, the first phase ramp information of any one or more ofExamples 1-24 optionally is different from the second phase rampinformation.

In Example 26, a mobile electronic device can include a processor, and awireless communication system configured to exchange information withthe processor and one or more other mobile electronic devices. Thewireless communication system can include a central frequencysynthesizer configured to provide a central synthesized signal having afirst frequency, a first wireless transmitter including a firsttransmitter DTC, the first DTC configured to receive the centralsynthesized signal and to provide a first transmitter signal having afirst transmitter frequency, and a wireless receiver including areceiver DTC, the receiver DTC configured to receive the centraloscillator signal and to provide a first receiver signal having areceiver frequency.

In Example 27, the first DTC of any one or more of Examples 1-26optionally is configured to receive first phase ramp information toprovide the first transmitter signal using the first phase rampinformation the central synthesized signal.

In Example 28, the mobile electronic device of any one or more ofExamples 1-14 optionally includes a second transmitter having a secondtransmitter DTC, the second transmitter DTC configured to receive thecentral synthesized signal and to provide a second transmitter signalhaving a second transmitter frequency.

In Example 29, the second transmitter DTC of any one or more of Examples1-28 optionally is configured to receive second phase ramp informationto provide the second transmitter signal using the second phase rampinformation and the central synthesized signal.

In Example 30, the first phase ramp information of any one or more ofExamples 1-31 optionally is different from the second phase rampinformation.

In Example 31, a digital-to-time converter (DTC) can include a delayelement configured to receive a periodic input signal and to provide aplurality of output phases using the periodic input signal, amultiplexer configured to receive selection information from acontroller and to couple one or more of the plurality of output phasesto an output of the multiplexer using the selection information, and aplurality of digital-to-analog converters (DACs) coupled to the outputof the multiplexer, to receive weight information from the controller,and to provide a plurality of analog signals representative of an outputsignal.

In Example 32, the DACs of any one or more of Examples 1-31 optionallyinclude current ADCs (iDACs) configured to provide a plurality of analogcurrent signals representative of the output signal.

In Example 33, the DTC of any one or more of Examples 1-32 optionallyincludes a summing node configured to sum the plurality of analogcurrent signals and to provide the output signal.

In Example 34, the selection information of any one or more of Examples1-33 optionally includes phase ramp information configured to shift afrequency of the output signal away from a frequency of the periodicinput signal.

In Example 35, the selection information of any one or more of Examples1-34 optionally includes phase modulation information configured toprovide phase modulation of the output signal.

In Example 36, weight information of any one or more of Examples 1-35optionally is configured to suppress noise at one or more a frequenciesof the output signal.

In Example 37, the delay element of any one or more of Examples 1-36optionally includes a delay line.

In Example 38, the delay element of any one or more of Examples 1-37optionally includes a divider circuit.

In Example 39, the delay element of any one or more of Examples 1-38optionally includes an delay interpolator.

Example 40 can include, or can optionally be combined with any portionor combination of any portions of any one or more of Examples 1 through39 to include, subject matter that can include means for performing anyone or more of the functions of Examples 1 through 39, or amachine-readable medium including instructions that, when performed by amachine, cause the machine to perform any one or more of the functionsof Examples 1 through 39.

The above detailed description includes references to the accompanyingdrawings, which form a part of the detailed description. The drawingsshow, by way of illustration, specific embodiments in which theinvention can be practiced. These embodiments are also referred toherein as “examples.” All publications, patents, and patent documentsreferred to in this document are incorporated by reference herein intheir entirety, as though individually incorporated by reference. In theevent of inconsistent usages between this document and those documentsso incorporated by reference, the usage in the incorporated reference(s)should be considered supplementary to that of this document; forirreconcilable inconsistencies, the usage in this document controls.

In this document, the terms “a” or “an” are used, as is common in patentdocuments, to include one or more than one, independent of any otherinstances or usages of “at least one” or “one or more.” In thisdocument, the term “or” is used to refer to a nonexclusive or, such that“A or B” includes “A but not B,” “B but not A,” and “A and B,” unlessotherwise indicated. In the appended claims, the terms “including” and“in which” are used as the plain-English equivalents of the respectiveterms “comprising” and “wherein.” Also, in the following claims, theterms “including” and “comprising” are open-ended, that is, a system,device, article, or process that includes elements in addition to thoselisted after such a term in a claim are still deemed to fall within thescope of that claim. Moreover, in the following claims, the terms“first,” “second,” and “third,” etc. are used merely as labels, and arenot intended to impose numerical requirements on their objects.

The above description is intended to be illustrative, and notrestrictive. For example, the above-described examples (or one or moreaspects thereof) may be used in combination with each other. Otherembodiments can be used, such as by one of ordinary skill in the artupon reviewing the above description. Also, in the above DetailedDescription, various features may be grouped together to streamline thedisclosure. This should not be interpreted as intending that anunclaimed disclosed feature is essential to any claim. Rather, inventivesubject matter may lie in less than all features of a particulardisclosed embodiment. Thus, the following claims are hereby incorporatedinto the Detailed Description, with each claim standing on its own as aseparate embodiment. The scope of the invention should be determinedwith reference to the appended claims, along with the full scope ofequivalents to which such claims are entitled.

What is claimed is:
 1. An apparatus comprising: an oscillator configuredto provide an oscillator signal having an oscillator frequency; aplurality of radios, at least one radio of the plurality of radiosincluding a digital-to-time converter (DTC) and configured to receivethe oscillator signal and to operate on a frequency different from theoscillator frequency; wherein the oscillator frequency is different froma radio frequency of a wireless signal of each radio of the plurality ofradios; and wherein each radio frequency of the wireless signal of theplurality of radios is different than the radio frequency of thewireless signal of each other radio of the plurality of radios.
 2. Theapparatus of claim 1, wherein a first radio of the plurality of radiosincludes a first transmitter.
 3. The apparatus of claim 2, wherein asecond radio of the plurality of radios includes a second transmitter.4. The apparatus of claim 3, wherein the second transmitter includes asecond transmit DTC configured to receive the oscillator signal and toprovide a second wireless transmit signal having a second wirelesstransmit frequency.
 5. The apparatus of claim 1, wherein the firsttransmitter includes a first transmit DTC configured to receive theoscillator signal and to provide a first wireless transmit signal havinga first wireless transmit frequency.
 6. The apparatus of claim 1,wherein the first radio of the plurality of radios includes a firstreceiver.
 7. The apparatus of claim 6, wherein the first receiverincludes a first receive DTC configured to receive the oscillator signaland to provide a first receiver signal having a first receive frequency.8. The apparatus of claim 6, wherein a second radio of the plurality ofradios includes a second receiver.
 9. The apparatus of claim 8, whereinthe second receiver includes a second receive DTC configured to receivethe oscillator signal and to provide a second receive signal having asecond receive frequency.
 10. The apparatus of claim 1, wherein theplurality of radios includes: a first transmitter including a firsttransmit digital-to-time converter (DTC) configured to receive theoscillator signal and to provide a first transmit signal having a firsttransmit frequency; and a first receiver, the first receiver configuredto receive the oscillator signal and to provide a first receiver signalhaving a first receive frequency.
 11. The apparatus of claim 10, whereinthe first transmit DTC is configured to receive phase modulationinformation and to provide the first transmit signal using the phasemodulation information.
 12. The apparatus of claim 10, wherein the firsttransmit DTC is configured to receive first phase ramp information andto provide the first transmit signal having the first transmit frequencyusing the first phase ramp information.
 13. The apparatus of claim 10,wherein the first transmitter is configured to process and transmitfirst information according to a first communication protocol; andwherein the first receiver is configured to receive and process secondinformation according to the first communication protocol.
 14. Anon-transitory machine-readable medium including instructions that, whenperformed by a machine, cause the machine to: generate an oscillatorsignal having an oscillator frequency using a central frequencysynthesizer; receive the oscillator signal at a plurality of radios, atleast one radio configured to process a first wireless signal having afirst radio frequency, the first radio frequency different than theoscillator frequency; receive, at the at least one radio, the oscillatorsignal at a digital-to-time converter (DTC) of the at least one radio;and generate the first wireless signal with the first radio frequencyusing the DTC of the at least one radio; wherein the oscillatorfrequency is different from a radio frequency of a wireless signal ofeach radio of the plurality of radios; and wherein the radio frequencyof the wireless signal of each radio of the plurality of radios isdifferent than the radio frequency of the wireless signal of each otherradio of the plurality of radios.
 15. The non-transitorymachine-readable medium of claim 14, including instructions that, whenperformed by e machine, cause the machine to: receive the oscillatorsignal at a first transmit DTC of a first transmitter radio of theplurality of radios; provide a first transmit wireless signal having afirst transmit frequency using the first transmit DTC; receive theoscillator signal at a second transmit DTC of a second transmitter radioof the plurality of radios; and provide a second transmit wirelesssignal having a second transmit frequency using the second transmit DTC.16. The non-transitory machine-readable medium of claim 14, includinginstructions that, when performed by the machine, cause the machine to:receive the oscillator signal at a first receiver DTC of a firstreceiver radio of the plurality of radios; provide a first receiversignal from a first received wireless signal having a first wirelessreceive frequency using the first receiver DTC; receive the oscillatorsignal at a second receiver DTC of a second receiver radio of theplurality of radios; and provide a second receiver signal from a secondreceived wireless signal having a second receive wireless frequencyusing the second receiver DTC.
 17. The non-transitory machine-readablemedium of claim 14, including instructions that, when performed by themachine, cause the machine to: receive the oscillator signal at a firstDTC of a first transmitter radio of the plurality of radios; generate afirst transmit signal having a first transmit wireless frequency usingthe first DTC; receive the oscillator signal at a second DTC of a firstreceiver radio of the plurality of radios; provide a first receiversignal from a first received wireless signal having a first wirelessreceive frequency using the second DTC; and wherein each of theoscillator frequency, the first transmit wireless frequency and thefirst receive wireless frequency is a different frequency than eachother frequency of the oscillator frequency, the first wireless transmitfrequency and the first wireless receive frequency.
 18. Thenon-transitory machine-readable medium of claim 17, includinginstructions that, when performed by the machine, cause the machine to:receive first phase ramp information at the first transmit DTC; andprovide the first transmit signal having the first wireless transmitfrequency using the first phase ramp information.
 19. The non-transitorymachine-readable medium of claim 17, wherein the first transmit wirelessfrequency and the first wireless receive frequency are different than aninteger harmonic frequency of the oscillator frequency.
 20. An apparatuscomprising: an oscillator configured to provide an oscillator signalhaving an oscillator frequency; a plurality of radios, at least oneradio of the plurality of radios including a digital-to-time converter(DTC) and configured to receive the oscillator signal and to operate ona frequency different from the oscillator frequency, and wherein theplurality of radios includes: a first transmitter including a firsttransmit digital-to-time converter (DTC) configured to receive theoscillator signal and to provide a first transmit signal having a firsttransmit frequency; and a first receiver, the first receiver configuredto receive the oscillator signal and to provide a first receiver signalhaving a first receive frequency; wherein each of the oscillatorfrequency, the first transmit frequency and the first receive frequencyis a different frequency than each other frequency of the oscillatorfrequency, the first transmit frequency and the first receive frequency;and wherein the first transmit DTC is configured to receive first phaseramp information and to provide the first transmit signal having thefirst transmit frequency using the first phase ramp information.